Amphoteric surface-active agents

ABSTRACT

THIS INVENTION RELATES TO AMPHOTERIC SURFACE-ACTIVE AGENTS HAVING THE GENERAL STRUCTURE:   R-CH(-CH3)-N(-R&#39;&#39;)-CH2-CH2-COO-M   WHEREIN R IS A STRAIGHT CHAIN ALKYL HAVING FROM 6 TO 16 CARBON ATOMS, R&#39;&#39; IS A LOWER ALKYL, AND M IS EITHER HYDROGEN, AN ALKALI METAL OR AN ALKYLOLAMINE.

United States Patent AMPHOTERIC SURFACE-ACTIVE AGENTS Zdzislaw W. Dudzinski, Clifton, N.J., and Reginald L. Wakeman, Philadelphia, Pa., assignors to Millmaster Onyx Corporation, New York, N.Y.

No Drawing. Original application Dec. 14, 1970, Ser. No. 98,144. Divided and this application May 31, 1972, Ser. No. 258,301

Int. Cl. C07c 101/12 US. Cl. 260-50111 ABSTRACT OF THE DISCLOSURE This invention relates to amphoteric surface-active agents having the general structure:

1 Claim R' 0 R-CH-IL-CHzCHzPJ-OM wherein R is a straight chain alkyl having from 6 to 16 carbon atoms, R is a lower alkyl, and M is either hydrogen, an alkali metal or an alkylolamine.

wherein R is a straight chain alkyl having from 6 to 16 carbon atoms; R is a lower alkyl, such as methyl or ethyl; and M is either hydrogen, an alkali metal or an alkylolamine radical, such as mono-, di-, or tri-ethanol, or propanol amine radicals.

These compounds may be readily prepared by the reaction of an N-lower-alkyl-N-Z-alkylamine with either acrylonitrile, an acrylate or acrylic acid, and are preferably prepared from alpha-olefins by methods known to the art; as for example, those described in US. Pats. Nos. 3,287,410; 3,287,411; 3,436,420; and 3,497,555. Alternatively they may be prepared from 2-alkanols as well as other materials and by other reaction procedures, al-

though it is preferred to prepare them from the very cheap and abundant alpha olefins such as are produced by a Ziegler type synthesis by polymerization of ethylene; or by the cracking of straight-chain parafiinic hydrocarbons.

Briefly, the procedures include hydrochlorination or hydrobromination in the presence of a catalyst such as' FeCl to produce the corresponding 2-haloalkanes in excellent yield; or by sulfating to produce the 2-alkyl sulfates. In either case, the intermediate products are then 3,712,918 Patented Jan. 23, 1973 ICC reacted with methylamine or ethylamine under pressure to yield the corresponding N-lower alkyl N-2-alkylamines.

More specifically, the amphoteric surface-active agents of the present invention may be prepared by reacting the aforesaid secondary Z-amines with, for example, acrylonispeeds the reaction, but is not essential. Reaction with acrylonitrile or methyl or ethyl acrylate may be conducted at a temperature of between 100 and 140 C. and at a pressure of between 10 p.s.i. and 60 p.s.i., as developed; alternatively, the reaction may be carried out at atmospheric pressure by gradual addition of the acrylic reagent below the surface. At about 100 C., the reaction is unnecessarily slow; about 130 C. is preferred, to avoid polymerization of the acrylic.

Reaction with acrylic acid may be conducted in aqueous medium at about -95 C. at atmospheric pressure.

Beta propiolactone reacts with the 2-amines at about 60120 C. at atmospheric pressure, as shown in the following Example 7.

The products so obtained are of value in'a multiplicity of applications. In this respect, because of their efficacy in strongly acid solution, they may be employed in pickling or other metal treating operations. They are also useful textile assistants, either by themselves or with other agents. They may also be used as dye levelers, softeners and wetting agents. In addition, they are effective emulsifying agents. Because of their amphoteric character, they may be combined with quaternary ammonium 'or with phenolic and other germicides and pesticides. They may furthermore, be employed in cosmetic preparations; for example in combination with sulfated fatty alcohols and the like, they make excellent shampoos and bubble baths.

The following examples are illustrative of the present invention, without, however, limiting it except as claimed:

EXAMPLE 1 weight titration) and grams or 1.7 mol of acrylonitrile were charged into an agitated pressure vessel wherein the mixture was heated to -140 C. for a period of seven hours; the initial pressure was about 60 p.s.i., falling to about 18 p.s.i. towards the end.

Samples were removed at intervals, and were titrated to determine the amount of unreacted acrylonitrile by the mercaptan reaction method described in American Cyanamid Companys The Chemistry of Acrylonitrile, (Second Edition, 1959) pages 61-62. After three hours, 7.3% of residual acrylonitrile was present; after five hours 3.0%, and after seven hours, 2.8%. Conversion was essentially complete to N-methyl-N-Z-tetradecyl-amino-beta EXAMPLE 2 143 grams or 0.5 mol of the 98% grade product Example 1 was treated with 22 grams of solid caustic soda in 10 grams of water and 5 grams of isopropanol, under reflux in an agitated round-bottom flask for two hours, at about 130 C. and ambient pressure.

After cooling to 80 C., 70 grams of isopropanol was added, and the reflux condenser was replaced with a totaltake-off condenser. The isopropanol was distilled off to der reflux at ambient pressure for five hours at about 88-90 C.

The product was a clear, light amber solution which remains completely soluble in acid and alkaline ranges In the same manner, the tetradecyl, hexadecyl and octadecyl homologs were prepared from the corresponding amines, heating from five to seven hours. All exhibited surface-active properties.

EXAMPLE 7 27 grams (or 0.1 mol) of N-methyl-N-2-hexadecylamine and 7.2 grams (or 0.1 mol) of acrylic acid,in 20 grams of distilled water and grams of isopropanol, was heated under reflux at ambient pressure at about 85 -94 C., for 13 hours, to yield a clear, water-soluble product having surface-active properties. The other homologous amines reacted similarly.

EXAMPLE 8 The alkylaminopropionic acids of the preceding examples may be converted into the corresponding amine oxides:

remove traces of ammonia. After cooling, 150 grams of I water and 40 grams of isopropanol were added. The pH was adjusted to 9.8 and the' concentration was adjusted to 40% active as thesodium salt of N-methyl-N-Z-tetradecyl-amino-beta propionic acid. This product was a viscous straw-colored solution having an isoelectric point between 4.5 and 6.0.

EXAMPLE 3 In the same manner as in Example 1, the dodecyl-, hexdecyland octadecyl-homologs of N-methyl-N-Z-alkylamino-beta-propionitrile were prepared from either crude or refined grades of N-methylN-2-alkylamines. Heating times ranged from 7 to 14 hours, temperatures from 110 to 140 C., the pressures varying accordingly. In each case, yields of 90%95% of theory were obtained of products of about 99% purity.

EXAMPLE 4 In a similar manner to that of Example 2, the nitriles of Example 3 were saponified, varying the amounts of alcohol and water, and, consequently, the reflux temperatures and the elapsed time. For example, 63 grams of the C homolog was saponified with 22 grams of 50% caustic soda solution and 50 grams of isopropanol at 88 C. under reflux for 13 hours: the C homolog, in the amount of 77.6 grams, with 11 grams of solid NaOH and 50 grams of ethanol (SD 40) at 84 C. for 7 hours; and the C homolog in the amount of 169.5 grams with 22 grams of solid NaOI-I, 80 grams of ethanol and grams of water at 84 C. for 11 hours. The pH in each case was adjusted to between 9.5 and 10.5, and the concentration to about 40% active.

EXAMPLE 5 Instead of acrylonitrile, the N-methyl-N-Z-alkylamines were reacted with acrylic acid, and also with acrylic esters such as methyl acrylates. The acrylic acid was inclined to produce small amounts of by-products; the acrylates are exceptionally desirable for their reaction characteristics, but are more costly than acrylonitrile. The end products are, however, the same. The reaction conditions for such esters as methyl acrylate or ethyl acrylate are substantially the same as for acrylonitrile.

EXAMPLE 6 RI R-CH-I ICHlCHZii-OM by treatment with a peroxide such as hydrogen peroxide, or with ozone. For example, 50.0 grams of N-methyl-N- 2-hexadecyl-beta-amino-sodium propionate, 40% active solution, was adjusted to pH 9.7,with hydrochloric acid and 8.0 grams of 33% hydrogen peroxide was added, in an agitated round-bottomed flask. The charge was heated at 60 C. for three hours, during which time the pH dropped to 7.9,and the residual hydrogen peroxide was negligible.

On cooling, the product was a light-colored viscous,

liquid, gelling at low temperatures.

In the same manner, 50.0 grams of a 40% active solution of N-methyl-N-2-tetradecyl-amino-beta-sodium propionate at pH 9.1 was heated with 9.1 grams of 33% hydrogen peroxide for two hours at 7080 C. The pH dropped to 5.9, and the excess hydrogen peroxide was minimal.

The light colored solution was less viscous than that of the Z-hexadecyl homolog.

EXAMPLE 9 Certain of the above preparations were tested for foaming properties in the Ross-Miles Foam Tester, at 0.25% active concentration in distilled water at 104 F., and at three pH levels,-4, 6 and 8. Among those tested were the 2-dodecyl, Z-tetradecyl and Z-hcxadecyl derivatives of Examples 2 and 4; and also a 2: 1. mixture of the d=odecyl and tetradecyl, and a 3:1 mixture of the tetradecyl and hexadecyl, at 0.25% total activity; these last being derived from available mixed alpha olefins.

EXAMPLE 10 The foam building or stabilizing properties of the mixed Z-dodecyl/Z-tetradecyl derivatives in mixture with an equal active weight of Maprofix WAC, a sodium lauryl sulfate, was tested in the Ross-Miles apparatus at 0.1% total active concentration in distilled waer at 104 F. The separate 2-dodecyl and Z-tetradecyl derivatives and the Maprofix WAC were also tested at 0.1% concentration, as well as the latter at 0.05% concentration.

TABLE II.--ROSS-MILES FOAM HEIGHT IN MILLIMETERS The products of this invention are elfective wetting agents. The standard Draves Wetting Test was applied at pH 6 and pH 8 at 75 F., in 0.1% active concentrationin distilled water:

TABLE III.DRAVES WETTING TIME IN SECONDS 2-alkyl component pH 6 pH 8 2-dodeeyl 30 l 23. 1 2-tetradeeyl l5. 3 8. 8 Maprofix WAC" 12. 9 11. 5

EXAMPLE 7 12 A typical shampoo formula illustrative of the wide variety of uses was prepared as follows for the purpose of evaluating the shampooing effect on human hair (percentages are by weight of active content):

The foaming test showed the following results:

TABLE IV.-ROSS-MILES FOAM HEIGHT IN MILLIMETERS 2-alkyl component pH Initial 1 minute 5 minutes 2'dodecyl 6 240 210 205 8 235 200 200 2-tetradecyl 6 230 195 195 8 230 200 195 The following procedure was used to test the performance as a shampoo: Five gram tresses of natural, brown European human hair, about eight inches in length, were first moistened by holding them under running tap water at 100-105 F. An eye-dropper calibrated to contain 1 gram of the agent to be tested was charged with such solution, and this was applied dropwise to the suspended tress, from top to bottom.

A latherwas worked up actively between thumb and forefinger, up and down for one minute; the quality of the lather was noted. The tress was then rinsed under running tap water of 100-105 F. The shampoo and rinse were repeated a second time. The Wet Comb Test comprises combining the tress while wet and observing its manageability. This was repeated after air-drying overnight, as the Dry Comb Test. The Static Test, a measure of the tendency to develop static, is reported as thespread in inches of the lower end of the tress after such combing, measuring from the center to one side of the spread, in inches.

The quality of the lather and the ease of combing were rated as follows: E=Excellent; VG=Very Good; G= Good; P=Poor; VP=Very Poor:

TABLE V.-TRESS TEST AT PH 7 Static Component Lather Wet comb Dry comb in.

2-dodecyl VG P P l 2-tetradeeyl VG VG E V-l EXAMPLE 13 The amine oxides of Example 8 were also tested for foaming and wetting properties, at pH 4, 6, 8 and 10 respectively, in each case at 0.25% active content in distilled water, at 104 F., in the case of the Ross-Miles and at 75 F., in the test.

TABLE VI.-ROSS-MILES FOAM HEIGHT IN MILLIMETERS 2-alky1 component pH Initial 1 minute 5 minutes 2 tetradecyl 4 190 170 150 (i 140 130 2-hexadecyl 4 15 10 10 6 15 10 10 TABLE VIL-DRAVES WETTING TEST The tetradecyl homolog is suitable as a shampoo additive, as a foam booster or stabilizer and as a hair conditioner. The hexadecyl homolog may be employed in creme rinses, as a skin or hair conditioner; and also as a textile conditioner.

The amphoteric surface-active agents of this invention are also effective in other cosmetic preparations; for example, along with an alkanolamide, such as Super-Amide L-9-C for bubble-bath formulations; as emulsifying agents, in creams and lotions, and the like.

They are useful auxiliaries in textile processing. In dye baths, they serve as dye-levelers, penetratingagents, and lubricating agents for all fibers. After dyeing, the lubrieating and softening characteristics carry over to serve to advantage in yarn-winding and sewability, and for allover reduction of softening agent needed in the finishing operation.

For example, 1% to 2% of a40% solution on the weight of the fabric, applied in the dyebox, prevents crock-marks, chafe and crows feet on acetate or rayon. On nylon/cotton, 3% on the weight of the fabric provides leveling and penetration in dyeing.

For acrylic package pressure dyeing, 5% to 7% on the weight of the fabric serves to provide a more uniform dyeing, the higher percentages for light shades, the lower for darker shades.

These a-mphoterics, and especially those of higher molecular weight, serve at 0.5% to 1.0% add-on as softeners for cotton, rayon and most synthetics; with normal fulling agents such as soap they offer a more lubricated handle, especially on wool.

Since they are amphoteric in nature, they may be used as a self-finish, at /z% to solids add-on; or they may be used in combination with aminoplast resins as a plasticizer.

They are effective corrosion inhibitors for metals, and hence they may be incorporated with aerosol formulations. Along with mineral acids such as, for example, phosphoric, they are useful as metal cleaning compounds.

They may be compounded with alkalis, including caustic soda and other agents to make heavy duty industrial cleaning agents. Along with such other agents as alkylaryl sulfonates, al'kanolamides and polyphosphates or silicates, they may be compounded as all purpose cleaners. With the aid of a thickening agent such as the modified celluloses and an alkali, they make effective oven cleaners.

Because oftheir amphoteric character, they may be combined with quaternary ammonium germicides on the 10 one hand, or with phenols on the other,to serve as germicidal and pesticidal cleansers.

Their foam boosting properties for other surfactants and their wetting properties are amply illustrated in the foregoing tables.

The invention claimed is:

1. An amine oxide having the structure:

References Cited UNITED STATES PATENTS 11/1966 Wakeman et al. 260-50l.13 3/1972 Ernst 260-534 R OTHER REFERENCES Chem. Abstracts, 56:5025e. Chem. Abstracts, 60:10867d. Chem. Abstracts, 66:20247b.

VIVIAN GARNER, Primary Examiner US. Cl. X.R. 

